In JavaScript, we have two ways of making a "class" and giving it public functions.

Method 1:

function MyClass() {
    var privateInstanceVariable = 'foo';
    this.myFunc = function() { alert(privateInstanceVariable ); }

Method 2:

function MyClass() { }

MyClass.prototype.myFunc = function() { 
    alert("I can't use private instance variables. :("); 

I've read numerous times people saying that using Method 2 is more efficient as all instances share the same copy of the function rather than each getting their own. Defining functions via the prototype has a huge disadvantage though - it makes it impossible to have private instance variables.

Even though, in theory, using Method 1 gives each instance of an object its own copy of the function (and thus uses way more memory, not to mention the time required for allocations) - is that what actually happens in practice? It seems like an optimization web browsers could easily make is to recognize this extremely common pattern, and actually have all instances of the object reference the same copy of functions defined via these "constructor functions". Then it could only give an instance its own copy of the function if it is explicitly changed later on.

Any insight - or, even better, real world experience - about performance differences between the two, would be extremely helpful.


7 Answers 7


See http://jsperf.com/prototype-vs-this

Declaring your methods via the prototype is faster, but whether or not this is relevant is debatable.

If you have a performance bottleneck in your app it is unlikely to be this, unless you happen to be instantiating 10000+ objects on every step of some arbitrary animation, for example.

If performance is a serious concern, and you'd like to micro-optimise, then I would suggest declaring via prototype. Otherwise, just use the pattern that makes most sense to you.

I'll add that, in JavaScript, there is a convention of prefixing properties that are intended to be seen as private with an underscore (e.g. _process()). Most developers will understand and avoid these properties, unless they're willing to forgo the social contract, but in that case you might as well not cater to them. What I mean to say is that: you probably don't really need true private variables...

  • 4
    @RajV, The prototype method is only declared once. The inner-function (non-prototype) needs to be declared on every instantiation -- I think this is what makes that approach slower. The calling of the method might actually be faster, as you said.
    – James
    Aug 29, 2012 at 16:01
  • 1
    @999 You are right. I didn't notice that the test is creating a new instance within the loop. But, here is the funny thing. I changed the test case to just test for the expense of the method call. jsperf.com/prototype-vs-this/2. Even there, you will see that calling a prototype method is about 10% faster. Any idea why?
    – RajV
    Aug 29, 2012 at 16:07
  • 2
    @RajV, your test was still running 'new T` on every iteration. The JSperf site will automatically test your snippets millions of time. You don't need to add your own loop. See here: jsperf.com/prototype-vs-this/3 ... the results seem the same though. Prototype method calling is slightly faster, which is odd.
    – James
    Aug 29, 2012 at 16:12
  • 4
    Does this still hold true in 2016?
    – Eric
    Jul 2, 2016 at 0:30
  • 1
    The reference link is no longer available.
    – Anson
    Dec 21, 2016 at 5:05

In the new version of Chrome, this.method is about 20% faster than prototype.method, but creating new object is still slower.

If you can reuse the object instead of always creating an new one, this can be 50% - 90% faster than creating new objects. Plus the benefit of no garbage collection, which is huge:


  • 3
    Looks like jsperf.com is on longer active. Is there any other perf measurements you have?
    – Eric
    Jul 2, 2016 at 23:43
  • jsPerf is up again. This test in Chrome 55 gives identical results to both, while using this is three times faster in Firefox 50.
    – Yay295
    Jan 23, 2017 at 22:04
  • That test is wrong. In the first one you instantiate the class then call the method every iteration. In the second one you instantiate the class once then only call the method each iteration.
    – jgmjgm
    Apr 3, 2017 at 21:24

It only makes a difference when you're creating lots of instances. Otherwise, the performance of calling the member function is exactly the same in both cases.

I've created a test case on jsperf to demonstrate this:



You might not have considered this, but putting the method directly on the object is actually better in one way:

  1. Method invocations are very slightly faster (jsperf) since the prototype chain does not have to be consulted to resolve the method.

However, the speed difference is almost negligible. On top of that, putting a method on a prototype is better in two more impactful ways:

  1. Faster to create instances (jsperf)
  2. Uses less memory

Like James said, this difference can be important if you are instantiating thousands of instances of a class.

That said, I can certainly imagine a JavaScript engine that recognizes that the function you are attaching to each object does not change across instances and thus only keeps one copy of the function in memory, with all instance methods pointing to the shared function. In fact, it seems that Firefox is doing some special optimization like this but Chrome is not.


You are right that it is impossible to access private instance variables from inside methods on prototypes. So I guess the question you must ask yourself is do you value being able to make instance variables truly private over utilizing inheritance and prototyping? I personally think that making variables truly private is not that important and would just use the underscore prefix (e.g., "this._myVar") to signify that although the variable is public, it should be considered to be private. That said, in ES6, there is apparently a way to have the both of both worlds!

  • Your first jsperf test case is flawed, as you are only calling that method on the same instance again and again. In fact, engines (both FF and Chrome) do optimise this heavily indeed (like you imagined), and the inlining that happens here makes your microbenchmark totally unrealistic.
    – Bergi
    Sep 5, 2015 at 21:51
  • @Bergi JSPerf says that it runs the setup code "before each clocked test loop, outside of the timed code region." My setup code creates a new instance using new, so doesn't that mean that the method is indeed not called on the same object again and again? I don't think JSPerf would be very useful if it didn't "sandbox" each test loop. Sep 5, 2015 at 22:21
  • 1
    No, it's a "test loop" - your code is run in a loop to measure speed. This test is executed multiple times to get averages, and before each of those tests and their respective loops the setup is run.
    – Bergi
    Sep 6, 2015 at 11:50
  • Ahh I see. Thanks for the clarification. I fiddled around with JSPerf and agree with your point. In order to guarantee using a different instance every time myMethod is called on the instance, I would need to create a new instance in the test code, not the setup code. The problem with that is that the test would then also be including the time it takes to instantiate the instance, when I really only want to measure the time it takes to call the method on the instance ... Any way to deal with this in JSPerf? Sep 6, 2015 at 20:05
  • 1
    You can just create multiple instances beforehand (in the setup), then use var x = instances[Math.floor(Math.random()*instances.length)]; x.myMethod() in the timed section. As long as the var x = … line is the same (and does the same) in all tests, any differences in speed can be attributed to the method invocation. If you think the Math code is too heavy, you can also try making a large instances array in setup and then put a loop over that in the test - you just have to make sure that the loop does not get unrolled.
    – Bergi
    Sep 6, 2015 at 20:23

You may use this approach and it will allow you to use prototype and access instance variables.

var Person = (function () {
    function Person(age, name) {
        this.age = age;
        this.name = name;

    Person.prototype.showDetails = function () {
        alert('Age: ' + this.age + ' Name: ' + this.name);

    return Person; // This is not referencing `var Person` but the Person function

}()); // See Note1 below


The parenthesis will call the function (self invoking function) and assign the result to the var Person.


var p1 = new Person(40, 'George');
var p2 = new Person(55, 'Jerry');
  • But you're still creating a new method with each instance so there's no memory saving by using the prototype here. May 3, 2020 at 13:27
  • @riscarrott No, it's not creating it with each instance. Only the constructor is called with each instance. You can also easily check it like this: p1.showDetails === p2.showDetails to prove it is both one function. May 3, 2020 at 17:15
  • Ah sorry, misread it. So what benefit are you getting by wrapping it with a self invoking fn? May 4, 2020 at 15:53
  • You execute it immediately so Person is defined afterwards and available for use. Using this approach you can define "static" methods too. Basically since JavaScript has no classes, this approach tries to accommodate that limitation. You may read more about it here. May 4, 2020 at 18:01

In short, use method 2 for creating properties/methods that all instances will share. Those will be "global" and any change to it will be reflected across all instances. Use method 1 for creating instance specific properties/methods.

I wish I had a better reference but for now take a look at this. You can see how I used both methods in the same project for different purposes.

Hope this helps. :)

  • Your link is no longer valid. Can you add code to your answer to illustrate your point?
    – Paul
    Aug 19, 2015 at 11:54

This answer should be considered an expansion of the rest of the answers filling in missing points. Both personal experience and benchmarks are incorporated.

As far as my experience goes, I use constructors to literally construct my objects religiously, whether methods are private or not. The main reason being that when I started that was the easiest immediate approach to me so it's not a special preference. It might have been as simple as that I like visible encapsulation and prototypes are a bit disembodied. My private methods will be assigned as variables in the scope as well. Although this is my habit and keeps things nicely self contained, it's not always the best habit and I do sometimes hit walls. Apart from wacky scenarios with highly dynamic self assembling according to configuration objects and code layout it tends to be the weaker approach in my opinion particularly if performance is a concern. Knowing that the internals are private is useful but you can achieve that via other means with the right discipline. Unless performance is a serious consideration, use whatever works best otherwise for the task at hand.

  1. Using prototype inheritance and a convention to mark items as private does make debugging easier as you can then traverse the object graph easily from the console or debugger. On the other hand, such a convention makes obfuscation somewhat harder and makes it easier for others to bolt on their own scripts onto your site. This is one of the reasons the private scope approach gained popularity. It's not true security but instead adds resistance. Unfortunately a lot of people do still think it's a genuinely way to program secure JavaScript. Since debuggers have gotten really good, code obfuscation takes its place. If you're looking for security flaws where too much is on the client, it's a design pattern your might want to look out for.
  2. A convention allows you to have protected properties with little fuss. That can be a blessing and a curse. It does ease some inheritance issues as it is less restrictive. You still do have the risk of collision or increased cognitive load in considering where else a property might be accessed. Self assembling objects let you do some strange things where you can get around a number of inheritance problems but they can be unconventional. My modules tend to have a rich inner structure where things don't get pulled out until the functionality is needed elsewhere (shared) or exposed unless needed externally. The constructor pattern tends to lead to creating self contained sophisticated modules more so than simply piecemeal objects. If you want that then it's fine. Otherwise if you want a more traditional OOP structure and layout then I would probably suggest regulating access by convention. In my usage scenarios complex OOP isn't often justified and modules do the trick.
  3. All of the tests here are minimal. In real world usage it is likely that modules will be more complex making the hit a lot greater than tests here will indicate. It's quite common to have a private variable with multiple methods working on it and each of those methods will add more overhead on initialisation that you wont get with prototype inheritance. In most cases is doesn't matter because only a few instances of such objects float around although cumulatively it might add up.
  4. There is an assumption that prototype methods are slower to call because of prototype lookup. It's not an unfair assumption, I made the same myself until I tested it. In reality it's complex and some tests suggest that aspect is trivial. Between, prototype.m = f, this.m = f and this.m = function... the latter performs significantly better than the first two which perform around the same. If the prototype lookup alone were a significant issue then the last two functions instead would out perform the first significantly. Instead something else strange is going on at least where Canary is concerned. It's possible functions are optimised according to what they are members of. A multitude of performance considerations come into play. You also have differences for parameter access and variable access.
  5. Memory Capacity. It's not well discussed here. An assumption you can make up front that's likely to be true is that prototype inheritance will usually be far more memory efficient and according to my tests it is in general. When you build up your object in your constructor you can assume that each object will probably have its own instance of each function rather than shared, a larger property map for its own personal properties and likely some overhead to keep the constructor scope open as well. Functions that operate on the private scope are extremely and disproportionately demanding of memory. I find that in a lot of scenarios the proportionate difference in memory will be much more significant than the proportionate difference in CPU cycles.
  6. Memory Graph. You also can jam up the engine making GC more expensive. Profilers do tend to show time spent in GC these days. It's not only a problem when it comes to allocating and freeing more. You'll also create a larger object graph to traverse and things like that so the GC consumes more cycles. If you create a million objects and then hardly touch them, depending on the engine it might turn out to have more of an ambient performance impact than you expected. I have proven that this does at least make the gc run for longer when objects are disposed of. That is there tends to be a correlation with memory used and the time it takes to GC. However there are cases where the time is the same regardless of the memory. This indicates that the graph makeup (layers of indirection, item count, etc) has more impact. That's not something that is always easy to predict.
  7. Not many people use chained prototypes extensively, myself included I have to admit. Prototype chains can be expensive in theory. Someone will but I've not measured the cost. If you instead build your objects entirely in the constructor and then have a chain of inheritance as each constructor calls a parent constructor upon itself, in theory method access should be much faster. On the other hand you can accomplish the equivalent if it matters (such as flatten the prototypes down the ancestor chain) and you don't mind breaking things like hasOwnProperty, perhaps instanceof, etc if you really need it. In either case things start to get complex once you down this road when it comes to performance hacks. You'll probably end up doing things you shouldn't be doing.
  8. Many people don't directly use either approach you've presented. Instead they make their own things using anonymous objects allowing method sharing any which way (mixins for example). There are a number of frameworks as well that implement their own strategies for organising modules and objects. These are heavily convention based custom approaches. For most people and for you your first challenge should be organisation rather than performance. This is often complicated in that Javascript gives many ways of achieving things versus languages or platforms with more explicit OOP/namespace/module support. When it comes to performance I would say instead to avoid major pitfalls first and foremost.
  9. There's a new Symbol type that's supposed to work for private variables and methods. There are a number of ways to use this and it raises a host of questions related to performance and access. In my tests the performance of Symbols wasn't great compared to everything else but I never tested them thoroughly.


  1. There are lots of discussions about performance and there isn't always a permanently correct answer for this as usage scenarios and engines change. Always profile but also always measure in more than one way as profiles aren't always accurate or reliable. Avoid significant effort into optimisation unless there's definitely a demonstrable problem.
  2. It's probably better instead to include performance checks for sensitive areas in automated testing and to run when browsers update.
  3. Remember sometimes battery life matters as well as perceptible performance. The slowest solution might turn out faster after running an optimising compiler on it (IE, a compiler might have a better idea of when restricted scope variables are accessed than properties marked as private by convention). Consider backend such as node.js. This can require better latency and throughput than you would often find on the browser. Most people wont need to worry about these things with something like validation for a registration form but the number of diverse scenarios where such things might matter is growing.
  4. You have to be careful with memory allocation tracking tools in to persist the result. In some cases where I didn't return and persist the data it was optimised out entirely or the sample rate was not sufficient between instantiated/unreferenced, leaving me scratching my head as to how an array initialised and filled to a million registered as 3.4KiB in the allocation profile.
  5. In the real world in most cases the only way to really optimise an application is to write it in the first place so you can measure it. There are dozens to hundreds of factors that can come into play if not thousands in any given scenario. Engines also do things that can lead to asymmetric or non-linear performance characteristics. If you define functions in a constructor, they might be arrow functions or traditional, each behaves differently in certain situations and I have no idea about the other function types. Classes also don't behave the same in terms as performance for prototyped constructors that should be equivalent. You need to be really careful with benchmarks as well. Prototyped classes can have deferred initialisation in various ways, especially if your prototyped your properties as well (advice, don't). This means that you can understate initialisation cost and overstate access/property mutation cost. I have also seen indications of progressive optimisation. In these cases I have filled a large array with instances of objects that are identical and as the number of instances increase the objects appear to be incrementally optimised for memory up to a point where the remainder is the same. It is also possible that those optimisations can also impact CPU performance significantly. These things are heavily dependent not merely on the code you write but what happens in runtime such as number of objects, variance between objects, etc.

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